Near Optimal Online Algorithms and Fast Approximation Algorithms for Resource Allocation Problems

Journal of the ACM (JACM) Pub Date : 2019-01-09 DOI:10.1145/3284177

Nikhil R. Devanur, K. Jain, Balasubramanian Sivan, Christopher A. Wilkens

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引用次数: 28

Abstract

We present prior robust algorithms for a large class of resource allocation problems where requests arrive one-by-one (online), drawn independently from an unknown distribution at every step. We design a single algorithm that, for every possible underlying distribution, obtains a 1−ε fraction of the profit obtained by an algorithm that knows the entire request sequence ahead of time. The factor ε approaches 0 when no single request consumes/contributes a significant fraction of the global consumption/contribution by all requests together. We show that the tradeoff we obtain here that determines how fast ε approaches 0, is near optimal: We give a nearly matching lower bound showing that the tradeoff cannot be improved much beyond what we obtain. Going beyond the model of a static underlying distribution, we introduce the adversarial stochastic input model, where an adversary, possibly in an adaptive manner, controls the distributions from which the requests are drawn at each step. Placing no restriction on the adversary, we design an algorithm that obtains a 1−ε fraction of the optimal profit obtainable w.r.t. the worst distribution in the adversarial sequence. Further, if the algorithm is given one number per distribution, namely the optimal profit possible for each of the adversary’s distribution, then we design an algorithm that achieves a 1−ε fraction of the weighted average of the optimal profit of each distribution the adversary picks. In the offline setting we give a fast algorithm to solve very large linear programs (LPs) with both packing and covering constraints. We give algorithms to approximately solve (within a factor of 1+ε) the mixed packing-covering problem with O(γ m log (n/δ)/ε2) oracle calls where the constraint matrix of this LP has dimension n× m, the success probability of the algorithm is 1−δ, and γ quantifies how significant a single request is when compared to the sum total of all requests. We discuss implications of our results to several special cases including online combinatorial auctions, network routing, and the adwords problem.

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资源分配问题的近最优在线算法和快速逼近算法

我们提出了一种先前的鲁棒算法，用于解决一类资源分配问题，其中请求一个接一个(在线)到达，每一步都独立于未知分布。我们设计了一个单一的算法，对于每一个可能的底层分布，它获得的利润是由一个提前知道整个请求序列的算法获得的利润的1−ε分数。当没有单个请求消耗/贡献所有请求的全局消耗/贡献的很大一部分时，因子ε接近于0。我们证明了我们在这里得到的决定ε接近0的速度的权衡是接近最优的:我们给出了一个几乎匹配的下界，表明权衡不能比我们得到的更好。超越静态底层分布的模型，我们引入了对抗性随机输入模型，其中对手可能以自适应方式控制在每个步骤中绘制请求的分布。在不限制对手的情况下，我们设计了一种算法，该算法在对抗序列的最差分布下获得可获得的最优利润的1−ε分数。进一步，如果算法为每个分配给定一个数字，即每个对手分配的最优利润可能，那么我们设计了一个算法，该算法实现对手选择的每个分配的最优利润加权平均值的1−ε分数。在离线环境下，我们给出了一种求解同时具有包装约束和覆盖约束的超大型线性规划的快速算法。我们给出了用O(γ m log (n/δ)/ε2) oracle调用近似解决(在1+ε范围内)混合包装覆盖问题的算法，其中该LP的约束矩阵的维数为nx m，算法的成功概率为1 - δ，并且γ量化了单个请求与所有请求的总和相比的重要性。我们讨论了我们的结果对几个特殊情况的影响，包括在线组合拍卖，网络路由和广告问题。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of the ACM (JACM)

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